Picture encoding device and picture encoding method

ABSTRACT

There is provided a picture encoding device that encodes a picture and encodes a difference quantization parameter in a unit of a quantization coding block which is divided from the picture and is a management unit of a quantization parameter. A quantization parameter calculator derives a quantization parameter of the quantization coding block to be encoded. A prediction quantization parameter derivation unit derives a prediction quantization parameter using the quantization parameters of a plurality of quantization coding blocks which precede the quantization coding block to be encoded in order of encoding. A difference quantization parameter generator derives a difference quantization parameter of the quantization coding block to be encoded, using a difference between the quantization parameter of the quantization coding block to be encoded and the prediction quantization parameter. A first bitstream generator encodes the difference quantization parameter of the quantization coding block to be encoded.

CROSS-REFERENCED TO RELATED APPLICATION

The present application is a Continuation Application of U.S.application Ser. No. 16/035,885, filed Jul. 16, 2018; which is aContinuation of U.S. application Ser. No. 14/478,572, filed Sep. 5,2014, now U.S. Pat. No. 10,063,874; which is a Continuation ofInternational Application of PCT/JP2013/001875, filed Mar. 19, 2013;which in turn claims the benefit of Japanese Application No.2012-073574, filed on Mar. 28, 2012; and Japanese Application No.2012-073575, filed on Mar. 28, 2012, the disclosures of whichApplications are incorporated by reference herein.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to a picture encoding and decodingtechnique, and more particularly, to a picture encoding and decodingtechnique using quantization parameter prediction encoding.

2. Description of the Related Art

A digital moving picture encoding system, such as MPEG-2 Part2(hereinafter, referred to as MPEG-2) or MPEG-4 Part10/H.264(hereinafter, referred to as AVC), divides a picture into blocks with apredetermined size, encodes the picture, and transmits a quantizationparameter indicating the roughness of quantization for a predictionerror signal (or simply a picture signal). An encoder side variablycontrols the quantization parameter in units of predetermined blocks. Inthis way, it is possible to control the amount of code or to improvesubjective picture quality.

Adaptive quantization has been generally used as a quantizationparameter control method for improving the subjective picture quality.In the adaptive quantization, the quantization parameter is changeddepending on the activity of each macroblock such that fine quantizationis performed in a flat portion in which deterioration is likely to bevisually conspicuous and rough quantization is performed in acomplicated portion of a picture in which deterioration is relativelyless likely to be conspicuous. That is, in a macroblock with highactivity in which the number of bits allocated during encoding is likelyto be large, the quantization parameter is changed such that a largequantization scale is set. As a result, it is possible to improve thesubjective picture quality while performing control such that the numberof bits in the encoded picture data is minimized.

In MPEG-2, it is determined whether the quantization parameter of theprevious block in order of encoding and decoding is identical to thequantization parameter of the block to be encoded and the quantizationparameter is transmitted when the quantization parameters are notidentical to each other. In AVC, difference encoding is performed on thequantization parameter of the block to be encoded, using thequantization parameter of the previous block in order of encoding anddecoding as a prediction value. This is based on the fact that, sincecode amount control is generally performed in order of encoding, thequantization parameter of the previous block in order of encoding isclosest to the quantization parameter of the coding block, and this isintended to suppress the information amount of the quantizationparameter to be transmitted.

Patent Literature 1: JP 2011-91772 A

The quantization parameter control method according to the related artuses the quantization parameter of the encoded previous block as aprediction quantization parameter, calculates the difference between theprediction quantization parameter and the quantization parameter of theblock to be encoded, and encodes the calculated difference quantizationparameter. According to this structure, the amount of code of thequantization parameter is reduced. However, in the structure in whichthe quantization parameter of the previous block is used as theprediction quantization parameter, when quantization parameter controlis performed by adaptive quantization, the difference quantizationparameter becomes large and the code amount increases.

SUMMARY OF THE INVENTION

The invention has been made in view of the above-mentioned problems andan object of the invention is to provide a technique for reducing theamount of code of the quantization parameter and improving encodingefficiency.

In order to solve the problem, according to an aspect of the presentinvention, a picture encoding device that encodes a picture and encodesa difference quantization parameter in a unit of a quantization codingblock which is divided from the picture and is a management unit of aquantization parameter, includes: a quantization parameter derivationunit (110) that derives a quantization parameter of the quantizationcoding block to be encoded; a prediction quantization parameterderivation unit (114) that derives a prediction quantization parameterusing the quantization parameters of a plurality of quantization codingblocks which precede the quantization coding block to be encoded inorder of encoding; a difference quantization parameter derivation unit(111) that derives a difference quantization parameter of thequantization coding block to be encoded, using a difference between thequantization parameter of the quantization coding block to be encodedand the prediction quantization parameter; and an encoder (112) thatencodes the difference quantization parameter.

According to another aspect of the present invention, there is provideda picture encoding method. The picture encoding method that encodes apicture and encodes a difference quantization parameter in a unit of aquantization coding block which is divided from the picture and is amanagement unit of a quantization parameter, includes: a quantizationparameter derivation step of deriving a quantization parameter of thequantization coding block to be encoded; a prediction quantizationparameter derivation step of deriving a prediction quantizationparameter using the quantization parameters of a plurality ofquantization coding blocks which precede the quantization coding blockto be encoded in order of encoding; a difference quantization parameterderivation step of deriving a difference quantization parameter of thequantization coding block to be encoded, using a difference between thequantization parameter of the quantization coding block to be encodedand the prediction quantization parameter; and an encoding step ofencoding the difference quantization parameter.

According to another aspect of the present invention, there is provideda transmission device. The transmission device includes: a packetprocessor that packetizes a bitstream encoded by a picture encodingmethod of encoding a difference quantization parameter in a unit of aquantization coding block, which is divided from a picture and is amanagement unit of a quantization parameter, together with the pictureto obtain a bitstream; and a transmitter that transmits the packetizedbitstream. The picture encoding method includes: a quantizationparameter derivation step of deriving a quantization parameter of thequantization coding block to be encoded; a prediction quantizationparameter derivation step of deriving a prediction quantizationparameter using the quantization parameters of a plurality ofquantization coding blocks which precede the quantization coding blockto be encoded in order of encoding; a difference quantization parameterderivation step of deriving a difference quantization parameter of thequantization coding block to be encoded, using a difference between thequantization parameter of the quantization coding block to be encodedand the prediction quantization parameter; and an encoding step ofencoding the difference quantization parameter.

According to another aspect of the present invention, there is provideda transmission method. The transmission method includes: a packetprocessing step of packetizing a bitstream encoded by a picture encodingmethod of encoding a difference quantization parameter in a unit of aquantization coding block, which is divided from a picture and is amanagement unit of a quantization parameter, together with the pictureto obtain a bitstream; and a transmission step of transmitting thepacketized bitstream. The picture encoding method includes aquantization parameter derivation step of deriving a quantizationparameter of the quantization coding block to be encoded, a predictionquantization parameter derivation step of deriving a predictionquantization parameter using the quantization parameters of a pluralityof quantization coding blocks which precede the quantization codingblock to be encoded in order of encoding, a difference quantizationparameter derivation step of deriving a difference quantizationparameter of the quantization coding block to be encoded, using adifference between the quantization parameter of the quantization codingblock to be encoded and the prediction quantization parameter; and anencoding step of encoding the difference quantization parameter.

According to an aspect of the present invention, a picture decodingdevice that decodes a picture and decodes a bitstream in which adifference quantization parameter is encoded in a unit of a quantizationdecoding block which is divided from the picture and is a managementunit of a quantization parameter, includes: a decoder (202) that decodesthe bitstream in the unit of the quantization decoding block andextracts a difference quantization parameter of the quantizationdecoding block to be decoded; a prediction quantization parameterderivation unit (205) that derives a prediction quantization parameterusing the quantization parameters of a plurality of quantizationdecoding blocks which precede the quantization decoding block to bedecoded in order of decoding; and a quantization parameter derivationunit (203) that adds the difference quantization parameter of thequantization decoding block to be decoded and the predictionquantization parameter to derive the quantization parameter of thequantization decoding block to be decoded.

According to another aspect of the present invention, there is provideda picture decoding method. The picture decoding method that decodes apicture and decodes a bitstream in which a difference quantizationparameter is encoded in a unit of a quantization decoding block which isdivided from the picture and is a management unit of a quantizationparameter, includes: a decoding step of decoding the bitstream in theunit of the quantization decoding block and extracting a differencequantization parameter of the quantization decoding block to be decoded;a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization decoding blocks which precede the quantizationdecoding block to be decoded in order of decoding; and a quantizationparameter derivation step of adding the difference quantizationparameter of the quantization decoding block to be decoded and theprediction quantization parameter to derive the quantization parameterof the quantization decoding block to be decoded.

According to another aspect of the present invention, there is provideda reception device. The reception device that receives a bitstream anddecodes the bitstream, includes: a receiver that receives a bitstreamobtained by packetizing a bitstream in which a difference quantizationparameter is encoded in a unit of a quantization decoding block, whichis divided from a picture and is a management unit of a quantizationparameter, together with the picture; a restoration unit that performspacket processing on the received packetized bitstream to restore thepacketized bitstream to an original bitstream; a decoder that decodesthe restored bitstream in the unit of the quantization decoding blockand extracts a difference quantization parameter of a quantizationdecoding block to be decoded; a prediction quantization parameterderivation unit that derives a prediction quantization parameter usingthe quantization parameters of a plurality of quantization decodingblocks which precede the quantization decoding block to be decoded inorder of decoding; and a quantization parameter derivation unit thatadds the difference quantization parameter of the quantization decodingblock to be decoded and the prediction quantization parameter to derivethe quantization parameter of the quantization decoding block to bedecoded.

According to another aspect of the present invention, there is provideda reception method. The reception method that receives a bitstream anddecodes the bitstream, includes: a reception step of receiving abitstream obtained by packetizing a bitstream in which a differencequantization parameter is encoded in a unit of a quantization decodingblock, which is divided from a picture and is a management unit of aquantization parameter, together with the picture; a restoration step ofperforming packet processing on the received packetized bitstream torestore the packetized bitstream to an original bitstream; a decodingstep of decoding the restored bitstream in the unit of the quantizationdecoding block to extract a difference quantization parameter of aquantization decoding block to be decoded; a prediction quantizationparameter derivation step of deriving a prediction quantizationparameter using the quantization parameters of a plurality ofquantization decoding blocks which precede the quantization decodingblock to be decoded in order of decoding; and a quantization parameterderivation step of adding the difference quantization parameter of thequantization decoding block to be decoded and the predictionquantization parameter to derive the quantization parameter of thequantization decoding block to be decoded.

Any combinations of the above-mentioned components and implementationsof the invention in the form of methods, devices, systems, recordingmedia, and computer programs may also be effective as additional modesof the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating the structure of a moving pictureencoding device having a prediction quantization parameter derivationmethod according to an embodiment;

FIG. 2 is a block diagram illustrating the structure of a moving picturedecoding device having the prediction quantization parameter derivationmethod according to the embodiment;

FIG. 3 is a diagram illustrating code amount control in an MPEG-2 TM5screen;

FIG. 4 is a diagram illustrating a quantization parameter predictionmethod in AVC;

FIG. 5 is a diagram illustrating an example of the order of an encodingprocess when hierarchical tree encoding is used;

FIG. 6 is a diagram illustrating an example of the prediction of aquantization parameter of the upper left quantization coding block in atree block which is divided by the hierarchical tree encoding;

FIG. 7 is a diagram illustrating an example of the prediction of aquantization parameter of the lower left quantization coding block inthe tree block which is divided by the hierarchical tree encoding;

FIG. 8 is a diagram illustrating an example of the prediction of thequantization parameter of the upper left quantization coding block inthe tree block which is divided by the hierarchical tree encoding;

FIG. 9 is a diagram illustrating the position of coding blocks which areneighboring in the vertical direction in code amount control in theMPEG-2 TM5 screen;

FIG. 10 is a diagram illustrating an example of a differencequantization parameter encoding table;

FIG. 11 is a diagram illustrating the relationship between the treeblock to be encoded and the encoded tree block;

FIG. 12 is a diagram illustrating the prediction source of the upperleft quantization coding block in the tree block divided by thehierarchical tree encoding;

FIG. 13 is a diagram illustrating the prediction source of the upperright quantization coding block in the tree block divided by thehierarchical tree encoding;

FIG. 14 is a diagram illustrating the prediction source of the lowerleft quantization coding block in the tree block divided by thehierarchical tree encoding;

FIG. 15 is a diagram illustrating the prediction source of the lowerright quantization coding block in the tree block divided by thehierarchical tree encoding;

FIG. 16 is a flowchart illustrating the derivation of a predictionquantization parameter;

FIG. 17 is a diagram illustrating an example of a predictionquantization parameter calculation process;

FIG. 18 is a diagram illustrating an example of a quantization codingblock; and

FIG. 19 is a diagram illustrating the relationship between spatiallyneighboring quantization coding blocks and a tree block.

DETAILED DESCRIPTION

The invention will now be described by reference to the preferredembodiments. This does not intend to limit the scope of the presentinvention, but to exemplify the invention.

An embodiment of the invention provides code amount control techniquethat derives an optimum prediction quantization parameter from thecoding information of a plurality of encoded blocks, calculates adifference from the prediction quantization parameter, and encodes thedifference, in order to reduce the amount of code of the quantizationparameter of the block to be processed, in a picture encoding methodwhich divides a picture into rectangular blocks with a predeterminedsize, further divides each rectangular block into one or a plurality ofquantization coding blocks, which are management units of quantizationparameters, and transmits a difference quantization parameter in unitsof the quantization coding blocks.

Embodiment 1

A moving picture encoding device 100 and a moving picture decodingdevice 200 according to preferred embodiments of the invention will bedescribed. FIG. 1 is a block diagram illustrating the structure of themoving picture encoding device 100 according to the invention andincludes a picture memory 101, a residual signal generator 102, anorthogonal transform and quantization unit 103, a second bitstreamgenerator 104, a dequantization and inverse orthogonal transform unit105, a decoding picture signal overlap unit 106, a decoding picturememory 107, a prediction picture generator 108, an activity calculator109, a quantization parameter calculator 110, a difference quantizationparameter generator 111, a first bitstream generator 112, a codinginformation storage memory 113, a prediction quantization parameterderivation unit 114, and a bitstream multiplexer 115. However, a thicksolid arrow which connects blocks indicates the flow of a picture signalof a picture and a thin solid arrow indicates the flow of a parametersignal for controlling encoding.

The picture memory 101 temporarily stores the picture signal to beencoded which is supplied in order of imaging/display time. The picturememory 101 supplies the stored picture signal to be encoded to theresidual signal generator 102, the prediction picture generator 108, andthe activity calculator 109 in units of predetermined pixel blocks. Atthat time, the pictures which are stored in order of imaging/displaytime are arranged in order of encoding and are output in units of pixelblocks from the picture memory 101.

The residual signal generator 102 performs the subtraction between thepicture signal to be encoded and a prediction signal generated by theprediction picture generator 108 to generate a residual signal andsupplies the residual signal to the orthogonal transform andquantization unit 103.

The orthogonal transform and quantization unit 103 performs orthogonaltransform and quantization on the residual signal using quantizationparameters which are calculated by the quantization parameter calculator110 to generate an orthogonally-transformed and quantized residualsignal and supplies the residual signal to the second bitstreamgenerator 104 and the dequantization and inverse orthogonal transformunit 105.

The second bitstream generator 104 performs entropy encoding on theorthogonally-transformed and quantized residual signal according to aprescribed syntax rule to generate a second bitstream and supplies thesecond bitstream to the bitstream multiplexer 115.

The dequantization and inverse orthogonal transform unit 105 performsdequantization and inverse orthogonal transform on theorthogonally-transformed and quantized residual signal supplied from theorthogonal transform and quantization unit 103 using the quantizationparameters calculated by the quantization parameter calculator 110 tocalculate the residual signal and supplies the residual signal to thedecoding picture signal overlap unit 106.

The decoding picture signal overlap unit 106 overlaps the predictionpicture signal generated by the prediction picture generator 108 and theresidual signal which has been subjected to the dequantization andinverse orthogonal transform by the dequantization and inverseorthogonal transform unit 105 to generate a decoding picture and storesthe decoding picture in the decoding picture memory 107. However, afiltering process may be performed on the decoding picture to reducedistortion, such as block distortion due to encoding, and the decodingpicture may be stored in the decoding picture memory 107. In this case,prediction coding information, such as a flag for identifying theinformation of a host filter, for example, a deblocking filter, isstored in the coding information storage memory 113, if necessary.

The prediction picture generator 108 performs intra prediction or interprediction on the basis of the picture signal supplied from the picturememory 101 and the decoding picture signal supplied from the decodingpicture memory 107 in the prediction mode to generate a predictionpicture signal. The intra prediction generates the prediction picturesignal using the block to be encoded among the blocks which are obtainedby dividing the picture signal supplied from the picture memory 101 intopredetermined blocks and the pixel signal of the neighboring encodedblock which is supplied from the decoding picture memory 107 and isneighboring to the block to be encoded in the same picture as thatincluding the block to be encoded. The inter prediction uses, as areference picture, the encoded picture, which is stored in the decodingpicture memory 107 and is arranged before or after the block to beencoded among the blocks which are obtained by dividing the picturesignal supplied from the picture memory 101 into predetermined blocks intime series in the picture (coding picture), performs block matchingbetween the coding picture and the reference picture to calculate amotion vector indicating the amount of motion, and performs motioncompensation from the reference picture on the basis of the amount ofmotion to generate the prediction picture signal. The generatedprediction picture signal is supplied to the residual signal generator102. Coding information, such as the motion vector obtained by theprediction picture generator 108, is stored in the coding informationstorage memory 113, if necessary. When a plurality of prediction modescan be selected, the prediction picture generator 108 evaluates, forexample, the amount of distortion between the generated predictionpicture signal and the original picture signal to determine the optimumprediction mode, selects the prediction picture signal which isgenerated by prediction in the determined prediction mode, and suppliesthe prediction picture signal to the residual signal generator 102. Inaddition, when the prediction mode is the intra prediction mode, theprediction picture generator 108 supplies the intra prediction mode tothe coding information storage memory 113 and the first bitstreamgenerator.

The activity calculator 109 calculates an activity which is acoefficient indicating the complexity or smoothness of the block to beencoded in the picture that is supplied from the picture memory 101 andsupplies the activity to the quantization parameter calculator 110. Thedetailed structure and operation of the activity calculator 109 will bedescribed below.

The quantization parameter calculator 110 calculates the quantizationparameter of the block to be encoded using the activity calculated bythe activity calculator 109 and supplies the quantization parameter tothe difference quantization parameter generator 111 and the codinginformation storage memory 113. The detailed structure and operation ofthe quantization parameter calculator 110 will be described below.

The difference quantization parameter generator 111 subtracts theprediction quantization parameters derived by the predictionquantization parameter derivation unit 114 from the quantizationparameter calculated by the quantization parameter calculator 110 tocalculate a difference quantization parameter and supplies thedifference quantization parameter to the first bitstream generator 112.

The first bitstream generator 112 encodes the difference quantizationparameter calculated by the difference quantization parameter generator111 according to a prescribed syntax rule to generate a first bitstreamand supplies the first bitstream to the bitstream multiplexer 115.

The coding information storage memory 113 stores the quantizationparameter of the encoded block. Although connection is not illustratedin FIG. 1, coding information, such as the prediction mode or the motionvector generated by the prediction picture generator 108, is also storedas information required to encode the next block to be encoded. Inaddition, coding information which is generated in units of pictures orslices is also stored, if necessary.

The prediction quantization parameter derivation unit 114 derives theprediction quantization parameter of the block to be subjected toquantization coding, using the quantization parameter of the encodedquantization coding block or the coding information, and supplies theprediction quantization parameter to the difference quantizationparameter generator 111. The detailed structure and operation of theprediction quantization parameter derivation unit 114 will be describedbelow.

The bitstream multiplexer 115 multiplexes the first bitstream and thesecond bitstream according to a prescribed syntax rule and outputs themultiplexed bitstream.

FIG. 2 is a block diagram illustrating the structure of the movingpicture decoding device 200 according to the invention which correspondsto the moving picture encoding device 100 illustrated in FIG. 1. Themoving picture decoding device 200 according to the embodiment includesa bitstream separator 201, a first bitstream decoder 202, a quantizationparameter generator 203, a coding information storage memory 204, aprediction quantization parameter derivation unit 205, a secondbitstream decoder 206, a dequantization and inverse orthogonal transformunit 207, a decoding picture signal overlap unit 208, a predictionpicture generator 209, and a decoding picture memory 210. Similarly tothe moving picture encoding device 100 illustrated in FIG. 1, a thicksolid arrow which connects blocks indicates the flow of a picture signalof a picture and a thin solid arrow indicates the flow of a parametersignal for controlling encoding.

Since the decoding process of the moving picture decoding device 200illustrated in FIG. 2 corresponds to the decoding process provided inthe moving picture encoding device 100 illustrated in FIG. 1, thedequantization and inverse orthogonal transform unit 207, the decodingpicture signal overlap unit 208, the prediction picture generator 209,the decoding picture memory 210, and the coding information storagememory 204 illustrated in FIG. 2 have functions corresponding to thefunctions of the dequantization and inverse orthogonal transform unit105, the decoding picture signal overlap unit 106, the predictionpicture generator 108, the decoding picture memory 107, and the codinginformation storage memory 113 of the moving picture encoding device 100illustrated in FIG. 1, respectively. However, the prediction picturegenerator 209 does not have the motion vector detection function and theprediction mode selection function of the prediction picture generator108 in the moving picture encoding device illustrated in FIG. 1.

The bitstream supplied to the bitstream separator 201 is separatedaccording to a prescribed syntax rule and the separated bitstream issupplied to the first bitstream decoder 202 and the second bitstreamdecoder 206.

The first bitstream decoder 202 decodes the supplied bitstream, outputscoding information related to, for example, the prediction mode, themotion vector, and the difference quantization parameter, gives thedifference quantization parameter to the quantization parametergenerator 203, and stores the coding information in the codinginformation storage memory 204.

The quantization parameter generator 203 adds the differencequantization parameter supplied from the first bitstream decoder 202 andthe quantization parameter derived by the prediction quantizationparameter derivation unit 205 to calculate a quantization parameter andsupplies the quantization parameter to the dequantization and inverseorthogonal transform unit 207 and the coding information storage memory204.

The coding information storage memory 204 stores the quantizationparameter of the decoded quantization coding block. The codinginformation storage memory 204 stores the coding information which isgenerated in units of pictures or slices, in addition to the codinginformation of each block which is decoded by the first bitstreamdecoder 202, if necessary. Although connection is not illustrated inFIG. 2, the decoded coding information, such as the prediction mode orthe motion vector, is supplied to the prediction picture generator 209.

The prediction quantization parameter derivation unit 205 derives aprediction quantization parameter using the quantization parameter ofthe decoded quantization coding block and supplies the predictionquantization parameter to the quantization parameter generator 203. Theprediction quantization parameter derivation unit 205 has the samefunctions as the prediction quantization parameter derivation unit 114of the moving picture encoding device 100 and the detailed structure andoperation of the prediction quantization parameter derivation unit 205will be described below.

The second bitstream decoder 206 decodes the supplied bitstream tocalculate the orthogonally-transformed and quantized residual signal andsupplies the orthogonally-transformed and quantized residual signal tothe dequantization and inverse orthogonal transform unit 207.

The dequantization and inverse orthogonal transform unit 207 performsinverse orthogonal transform and dequantization on theorthogonally-transformed and quantized residual signal decoded by thesecond bitstream decoder 206 using the quantization parameter generatedby the quantization parameter generator 203 to obtain aninverse-orthogonally-transformed and dequantized residual signal.

The decoding picture signal overlap unit 208 overlaps the predictionpicture signal which is generated by the prediction picture generator209 and the residual signal which is subjected to the inverse orthogonaltransform and dequantization by the dequantization and inverseorthogonal transform unit 207 to generate a decoding picture signal,outputs the decoding picture signal, and stores the decoding picturesignal in the decoding picture memory 210. When the decoding picturesignal is stored in the decoding picture memory 210, a filtering processmay be performed on the decoding picture to reduce distortion, such asblock distortion due to encoding, and the decoding picture may be storedin the decoding picture memory 210.

The prediction picture generator 209 generates a prediction picturesignal from the decoding picture signal supplied from the decodingpicture memory 210, on the basis of the coding information, such as theprediction mode or the motion vector, decoded by the second bitstreamdecoder 206 and the coding information from the coding informationstorage memory 204 and supplies the prediction picture signal to thedecoding picture signal overlap unit 208.

Next, a prediction quantization parameter derivation method which iscommonly performed by some units 120 that are surrounded by a thickdotted line in the moving picture encoding device 100, particularly, theprediction quantization parameter derivation unit 114 and some units 220that are surrounded by a thick dotted line in the moving picturedecoding device 200, particularly, the prediction quantization parameterderivation unit 205 will be described in detail below.

First, the operation of each of some units 120 surrounded by the thickdotted line in the moving picture encoding device 100 according to thisembodiment will be described. Some units 120 use a pixel block with apredetermined pixel size which is supplied from the picture memory 101as a quantization coding block and determines the quantization parameterfor quantizing the quantization coding block. The quantization parameteris mainly determined by an encoder side using code amount control andadaptive quantization algorithm and is transmitted to a decoder sidethat performs a quantization parameter prediction process. First, anadaptive quantization method of the activity calculator 109 will bedescribed.

In general, the visual characteristics of the human eye are sensitive toa low-frequency component with a small edge. Therefore, the activitycalculator 109 calculates an activity for achieving the complexity orsmoothness of a picture in units of predetermined quantization codingblocks such that fine quantization is performed in a flat portion of thepicture in which deterioration is likely to be visually conspicuous andrough quantization is performed in a complicated portion of the picturein which deterioration is relatively less likely to be conspicuous.However, the activity calculation process is included only in theencoding device, but is not included in the decoding device. Here, theactivity is calculated for each quantization coding block. However, theinvention is not limited thereto, but the encoder side may freelydetermine the unit of activity calculation, considering complexity.

For example, the activity is calculated by the variance value of a pixelin the coding block, which is described in MPEG-2 Test Model 5 (TM5).The variance value indicates the degree of dispersion of the value of apixel forming the picture in the block from the average value. Thevariance value decreases as the flatness of a portion of the picture inthe block increases (a change in brightness is reduced) and increases asthe complexity of a portion of the picture increases (the change inbrightness increases). Therefore, the variance value is used as theactivity of the block. When a pixel value in the block is represented byp (x, y), the activity act of the block is calculated by the followingexpression.act=x,yBLK(p(x,y)−p_mean)2  [Expression 1] ##EQU00001##

Here, BLK indicates the total number of pixels in the quantizationcoding block and p_mean indicates the average value of the pixels in theblock.

The activity is not limited to the variance. For example, the absolutevalues of the differences between the pixel in the quantization codingblock and pixels which are neighboring to the pixel in the horizontaldirection and the vertical direction and the sum of the absolute valuesin the block may be calculated. In this case, the value is small in aflat portion of the picture and is large in a complication portion ofthe picture with a large edge. The value can also be used as theactivity. The activity is calculated by the following expression.act=x,yBLK(p(x,y)−p(x+1,y)+p(x,y)−p(x,y+1))  [Expression 2] ##EQU00002##

The calculated activity act is supplied to the quantization parametercalculator 110.

Next, code amount control will be described. In the moving pictureencoding device 100 according to this embodiment, particularly, a unitfor achieving code amount control is not provided. In the followingdescription, in the code amount control, the quantization parametercalculator 110 has code amount control function in order to determinethe quantization parameter of the coding block, on the basis of theamount of code generated.

The code amount control is performed to approximate the generated codeamount of a predetermined unit, such as a picture or a slice, to atarget code amount. When it is determined that the generated code amountof the encoded block is more than the target code amount, roughquantization is relatively applied to the quantization coding blockwhose quantization parameter is to be encoded. When it is determinedthat the generated code amount of the encoded block is less than thetarget code amount, fine quantization is relatively applied to the blockto be encoded.

The detailed code amount control algorithm will be described withreference to FIG. 3.

First, a target code amount (T) is determined for each picture. Ingeneral, the target code amount (T) is determined such that thefollowing relationship is established: an I picture>a P picture>areference B picture>a non-reference B picture. For example, in a case inwhich the target bit rate of a moving picture is 5 Mbps, the number of Ipictures per second is 1, the number of P pictures per second is 3, thenumber of reference B pictures per second is 11, and the number ofnon-reference B pictures per second is 15, the target code amounts ofpicture types are Ti, Tp, Tbr, and Tb, when the target code amount isdesired to be control such that Ti:Tp:Tbr:Tb=4:3:2:1 is established,Ti=400 kbit, Tp=300 kbit, Tbr=200 kbit, and Tb=100 kbit are established.However, the code amount allocated to each picture type does not have aneffect on the essence of the invention.

Next, code amount control in the picture will be described. When thenumber of blocks, which are units determining the quantizationparameters, is N, the generated code amount is B, and a difference bitbetween the target code amount and the generated code amount is D, thefollowing expression is satisfied.D(j)=D(0)+B(j−1)−T(j−1)N  [Expression 3] ##EQU00003##

Here, j indicates the encoding order count number of the quantizationcoding block. D(0) indicates the initial value of a target code amountdifference.

A quantization parameter bQP is determined by code amount control asfollows.bQP(j)=D(j).times.r  [Expression 4]

Here, r indicates a proportional coefficient for converting the targetcode amount difference into a quantization parameter. The proportionalcoefficient r is determined according to usable quantization parameters.

The quantization parameter calculator 110 changes the quantizationparameter of the coding block calculated by the code amount control,using the activity act which is calculated for each quantization codingblock by the activity calculator 109. Hereinafter, since thequantization parameter is calculated for each quantization coding block,it is assumed that the encoding order count number of the quantizationparameter by the code amount control is removed and the quantizationparameter is represented by bQP.

The quantization parameter calculator 110 records the average activityof the previous encoded picture as avg_act and calculates the normalizedactivity Nact of the coding block using the following expression.Nact=2.times.act+avg_act act+2.times.avg_act  [Expression 5]##EQU00004##

In the above-mentioned expression, the coefficient “2” is a valueindicating the dynamic range of the quantization parameter and anormalized activity Nact is calculated in the range of 0.5 to 2.0.However, the coefficient of the quantization parameter is not limited to2, but may be other values depending on, for example, thecharacteristics of the picture.

For avg_act, the activity may be calculated for all blocks in thepicture in advance before the encoding process and the average value ofthe activities may be calculated as avg_act. In addition, avg_act may bestored in the coding information storage memory 113 or the quantizationparameter calculator 110 may acquire avg_act from the coding informationstorage memory 113, if necessary.

The calculated normalized activity Nact is multiplied by thequantization parameter bQP which is a reference parameter to obtain aquantization parameter QP of the coding block, as represented by thefollowing expression.QP=Nact.times.bQP  [Expression 6]

The calculated quantization parameter of the coding block is supplied tothe coding information storage memory 113 and the differencequantization parameter generator 111.

The coding information storage memory 113 stores the quantizationparameter calculated by the quantization parameter calculator 110 or thequantization parameter of the past encoded quantization coding block andcoding information, such as the motion vector of the coding block or theprediction mode. Each unit derives the coding information, if necessary.

The prediction quantization parameter derivation unit 114 derives theprediction quantization parameter which is required to efficientlyencode the quantization parameter of the coding block and to transmitthe quantization parameter, using the encoded quantization parameterfrom the coding information storage memory 113.

A method which calculates the difference (difference quantizationparameter) between the quantization parameter and the predictionquantization parameter which is predicted from the quantizationparameter of the encoded quantization coding block, encodes thedifference quantization parameter, and transmits the differencequantization parameter is more efficient in encoding and transmittingthe quantization parameter than a method which transmits thequantization parameter without any change. In terms of code amountcontrol, when the quantization parameter of the previous encoded blockin order of encoding is used as the prediction quantization parameter,the value of the difference quantization parameter to be transmitted isreduced and the amount of code is reduced. In contrast, in terms ofadaptive quantization, since a quantization coding block generally has asimilar pattern to a neighboring quantization coding block, the activityof the neighboring quantization coding block close to the quantizationcoding block is approximate to the activity of the coding block.

When the quantization parameter of the neighboring quantization codingblock is used as the prediction quantization parameter, the value of thedifference quantization parameter to be transmitted is reduced and theamount of code is reduced. Therefore, in AVC, a method is used in whichthe transmission unit of the quantization parameter is fixed to a macroblock (a 16.times.16 pixel group), the quantization parameter of theneighboring block which is arranged on the left side of the coding blockand is encoded immediately before the coding block in a raster scanningorder is used as the prediction quantization parameter, the differencebetween the quantization parameter of the coding block and theprediction quantization parameter is calculated, and the differencequantization parameter is encoded and transmitted, as illustrated inFIG. 4. That is, AVC is most suitable for the prediction of thequantization parameter by the code amount control. However, in AVC,hierarchical tree encoding, which will be described below, is notperformed. Therefore, in a portion of the picture other than the leftend, since the previous block is the left block, the quantizationparameter of a neighboring block is used as the prediction quantizationparameter and AVC is substantially most suitable for prediction usingadaptive quantization. Thus, as in the structure, such as AVC, in whichthe transmission unit of the quantization parameter is fixed andhierarchical tree encoding is not performed, the previous encoded blockis also most suitable for the prediction of the quantization parameter.

However, in the case in which the hierarchical tree encoding isperformed, when the quantization parameter of the previous block is usedas the prediction quantization parameter similarly to AVC, predictionwhich is most suitable for code amount control is performed. However,when the quantization parameter is transmitted using adaptivequantization, there is a problem that an optimum prediction value is notobtained and the amount of code of the difference quantization parameterincreases.

Here, the hierarchical tree encoding will be described. The hierarchicaltree encoding determines a depth indicating the unit of encoding in eachtree block (here, 64.times.64 blocks) and performs quantization codingfor each coding block at the determined depth. In this way, it ispossible to determine the optimum depth which depends on the definitionof the picture and to perform quantization coding at the determinedoptimum depth. Therefore, encoding efficiency is significantly improved.

FIG. 5 illustrates the encoding order of a hierarchical tree encodingstructure. As illustrated in the upper diagram of FIG. 5, a screen isequally divided into square units with the same size. The unit is calleda tree block and is the basic unit of address management for specifyingan encoding/decoding block in the picture. The tree block can behierarchically divided into four small blocks, depending on, forexample, texture in the picture, in order to optimize the encodingprocess, if necessary. The hierarchical block structure formed bydividing the tree block into small blocks is referred to as a tree blockstructure and the divided block is referred to as a coding block (CU)and is the basic unit of processing when encoding and decoding areperformed. The lower diagram of FIG. 5 illustrates an example in which,among four CUs divided from the tree block, each of three CUs except forthe lower left CU is further divided into four blocks.

In this embodiment, it is assumed that the CU and the quantizationcoding block are set to the same unit, that, the quantization parameteris set for each CU. The tree block is the coding block with the maximumsize. However, the unit of the quantization coding block may not be thesame as the CU, but may be a predetermined independent unit. That is,the quantization coding block does not depend on the size of the CU, butmay be fixed to a 16.times.16 block unit. Next, an example in which theunit of the quantization coding block is not the same as the CU will bedescribed.

In the hierarchical tree encoding, since the order of encoding isdifferent from the raster scanning order (from the left to the right) asin AVC illustrated in FIG. 4, in many cases, the quantization parameterof the previous encoded block is not the same as that of the leftneighboring block. In an example of the hierarchical tree encoding, asillustrated in FIG. 6, the upper left quantization coding block (ahatched rectangle in FIG. 6) in the tree block to be encoded uses thequantization parameter of the lower right encoded block (a grayrectangle in FIG. 6), which has been encoded last among the blocksdivided from the tree block that is neighboring on the left side of thetree block to be encoded, for prediction. In addition, as illustrated inFIG. 7, the lower left quantization coding block (a hatched rectangle inFIG. 7) in the tree block to be encoded uses the quantization parameterof the block (a gray rectangle in FIG. 7), which is divided from thesame tree block and is previously quantized and encoded, for prediction.Therefore, when the quantization parameter is predicted only from theprevious encoded block, prediction which is most suitable for codeamount control can be performed, but it is difficult to performprediction suitable for adaptive quantization since there is a gapbetween the divided blocks. As a result, the amount of code of thedifference quantization parameter increases and encoding efficiency isreduced.

When the quantization parameter of the left neighboring quantizationcoding block is constantly used as the prediction quantizationparameter, as illustrated in FIG. 8, the prediction quantizationparameter of the upper left quantization coding block in the tree blockis further away from that of the quantization coding block in theprevious tree block as the number of quantization coding blocks dividedfrom the previous tree block increases. Therefore, encoding efficiencyis reduced in terms of code amount control in which the predictionefficiency of the quantization parameter increases as the prediction isperformed from the closer quantization coding block in order ofencoding.

That is, when the quantization parameter is predicted from the spatiallyneighboring quantization coding block, in some cases, the quantizationparameter which was calculated long before the quantization coding blockis used. Therefore, as illustrated in FIG. 9, for the processing order jof the quantization coding block and the processing order i of thespatially neighboring quantization coding block, even when thequantization coding blocks are spatially neighboring to each other, i<<jis satisfied in order of encoding in terms of code amount control, asillustrated in FIG. 9. Therefore, there is a high correlation betweenthe quantization parameters of the neighboring quantization codingblocks. In addition, when the quantization parameter is predicted onlyfrom the quantization coding blocks which are close in order of encodingamong the spatially quantization coding blocks, it is determined whetherthe spatially neighboring quantization coding block is out of the treeblock. When the spatially neighboring quantization coding block is outof the tree block, it is determined that the spatially neighboringquantization coding block is the quantization coding block which is awayin order of encoding and only the quantization parameter in the treeblock is used for prediction. Therefore, it is possible to avoid thederivation of an improper quantization parameter in terms of code amountcontrol. However, in some cases, the optimum process is not necessarilyperformed in terms of code amount control. For example, a process isrequired which determines whether the spatially neighboring quantizationcoding block, which is the prediction unit of the quantizationparameter, is out of the tree block, or the quantization coding block isdisposed in the tree block, but is not away in order of encoding.

Here, the prediction quantization parameter derivation unit 114according to the embodiment of the invention derives the predictionquantization parameter using the quantization parameters of a pluralityof previous quantization coding blocks. Therefore, a method is achievedwhich can predict the quantization parameters from the spatiallyneighboring quantization coding blocks which have high predictionefficiency in terms of adaptive quantization, while using thequantization parameters of quantization coding blocks which are close toeach other in order of encoding and have high prediction efficiency interms of code amount control. In addition, the storage of thequantization parameters for deriving the spatially neighboringquantization parameters is minimized and the quantization parameter ispredicted with a small amount of memory. The prediction quantizationparameter derivation unit 114 will be described in detail below.

The difference quantization parameter generator 111 performs thesubtraction between the quantization parameter of the quantizationcoding block calculated by the quantization parameter calculator 110 andthe prediction quantization parameter derived by the predictionquantization parameter derivation unit 114 to calculate a differencequantization parameter. The prediction quantization parameter is derivedfrom the decoded quantization coding block during decoding by the samemethod as that during encoding. When the difference encoding parameteris encoded, there is no inconsistency between encoding and decoding andit is possible to reduce the amount of code of the quantizationparameter. The calculated difference quantization parameter is suppliedto the first bitstream generator 112.

The first bitstream generator 112 performs entropy encoding on thedifference quantization parameter calculated by the differencequantization parameter generator 111 according to a prescribed syntaxrule to generate the first bitstream. FIG. 10 illustrates an example ofan encoding conversion table which is used to perform entropy encodingon the difference quantization parameter. In the table, for example, afirst bit indicates that a difference quantization parameter with thehighest frequency of appearance is 0, a second bit indicates a positiveflag, a third bit indicates whether the absolute value of the differencequantization parameter is 1, and a fourth bit indicates whether theabsolute value of the difference quantization parameter is 2. In theencoding of the difference quantization parameter, a shorter code lengthis given to the difference quantization parameter with a smallerabsolute value and the absolute value of the difference quantizationparameter is known by the bit length. Therefore, it is possible tosuppress the generated code amount of the difference quantizationparameter with a simple structure. FIG. 10 illustrates the encodingtable in which the bit length increases in proportion to the absolutevalue of the difference quantization parameter. Therefore, when a smalldifference quantization parameter is transmitted, the generated codeamount is significantly reduced. When a large difference quantizationparameter is transmitted, the generated code amount is relatively large.When the difference quantization parameter is encoded using the encodingtable illustrated in FIG. 10, it is important not only to improve theprobability of the difference quantization parameter being zero, butalso to derive the prediction quantization parameter which minimizes thegeneration of a difference quantization parameter with a large value.The first bitstream generator 112 extracts a bitstream corresponding tothe difference quantization parameter from FIG. 10 and supplies thebitstream to the bitstream multiplexer 115.

The operation of each of some units 220 which are surrounded by a thickdotted line in the moving picture decoding device 200 corresponding tothe moving picture encoding device 100 according to this embodiment willbe described.

In some units 220, first, the difference quantization parameter decodedby the first bitstream decoder 202 is supplied to the quantizationparameter generator 203. In addition, coding information other than thedifference quantization parameter is stored in the coding informationstorage memory 204, if necessary.

The quantization parameter generator 203 adds the differencequantization parameter supplied from the first bitstream decoder 202 andthe quantization parameter derived by the prediction quantizationparameter derivation unit 205 to calculate the quantization parameter ofa decoding block and supplies the calculated quantization parameter tothe dequantization and inverse orthogonal transform unit 207 and thecoding information storage memory 204.

The coding information storage memory 204 stores the quantizationparameter of the decoded quantization coding block. In addition, thecoding information storage memory 204 stores coding information which isgenerated for each picture or slice as well as the coding information ofeach block which is decoded by the first bitstream decoder 202, ifnecessary.

The prediction quantization parameter derivation unit 205 derives theprediction quantization parameter using the quantization parameter ofthe decoded block and supplies the prediction quantization parameter tothe quantization parameter generator 203. The quantization parametercalculated by the quantization parameter generator 203 is stored in thecoding information storage memory 204 and is used to derive theprediction quantization parameter of the quantization coding block to bedecoded in the subsequent process. The decoded quantization parameter isthe same as the quantization parameter which is derived from the codinginformation storage memory 113 by the prediction quantization parameterderivation unit 114 of the moving picture encoding device 100. Theprediction quantization parameter derivation unit 205 has the samefunctions as the prediction quantization parameter derivation unit 114of the moving picture encoding device 100. Therefore, when the samequantization parameter is supplied from the coding information storagememory 204, the prediction quantization parameter derivation unit 205derives the same prediction quantization parameter as that duringencoding.

The prediction quantization parameter which is derived by the encoderside is derived on the decoder side without any inconsistency.

Next, a prediction quantization parameter derivation method which iscommonly performed by the prediction quantization parameter derivationunits 114 and 205 will be described in detail.

The detailed operation of the prediction quantization parameterderivation unit 114 will be described. As illustrated in FIG. 11,encoding is performed for each tree block in a raster scanning orderfrom the upper left side to the lower right side of the screen. When thetree block to be encoded is represented by a hatched rectangle in FIG.11, the encoded tree block is represented by a gray portion in FIG. 11.In the tree block, hierarchical tree encoding is performed according toencoding conditions and the coding block is divided with a size that isless than or equal to that of the tree block. The coding block in thetree block to be encoded is neighboring to the encoded block in a treeblock that is disposed above the tree block to be encoded, but thecoding block and the encoded block are greatly separated from each otherin order of encoding. Therefore, since the quantization parameter iscalculated by code amount control in order of encoding, the quantizationparameter of the coding block is not close to the quantization parameterof the encoded block in the tree block which is disposed above the treeblock to be encoded. For this reason, the prediction quantizationparameter is encoded using the quantization parameters of a plurality ofprevious quantization coding blocks.

FIGS. 12 to 15 illustrate the prediction source of the upper left, upperright, lower left, and lower right quantization coding blocks which aredivided from the tree block by hierarchical tree encoding.

In the upper left quantization coding block in the tree blockillustrated in FIG. 12, a quantization parameter prevQP1 of a previousquantization coding block in order of encoding and a quantizationparameter prevQP2 of a quantization coding block before the previousquantization coding block in order of encoding are derived from twoquantization coding blocks in a previous tree block, respectively.

In the right quantization coding block in the tree block illustrated inFIG. 13, the quantization parameter prevQP1 of the previous quantizationcoding block in order of encoding and the quantization parameter prevQP2of the quantization coding block before the previous quantization codingblock in order of encoding are derived from the left quantization codingblock in the same tree block and one quantization coding block in theprevious tree block, respectively.

In the lower left quantization coding block in the tree blockillustrated in FIG. 14, the quantization parameter prevQP1 of theprevious quantization coding block in order of encoding and thequantization parameter prevQP2 of the quantization coding block beforethe previous quantization coding block in order of encoding are derivedfrom the upper right quantization coding block and the upperquantization coding block in the same tree block, respectively.

In the lower right quantization coding block in the tree blockillustrated in FIG. 15, the quantization parameter prevQP1 of theprevious quantization coding block in order of encoding and thequantization parameter prevQP2 of the quantization coding block beforethe previous quantization coding block in order of encoding are derivedfrom the left right quantization coding block and the upper quantizationcoding block in the same tree block, respectively.

The prediction quantization parameter is determined by the average valueof prevQP1 and prevQP2.predQP=prevQP1+prevQP2+12  [Expression 7] ##EQU00005##

In the examples illustrated in FIGS. 12 and 13, the quantization codingblocks which are spatially separated from each other are the predictionsource of the quantization parameters and the average value of thequantization parameters is calculated. Therefore, even when thequantization parameter prevQP1 has low reliability due to an unexpectedfactor, errors are averaged and the prediction efficiency of thequantization parameter is improved. Even though the quantization codingblocks which are spatially separated from each other are used, theaverage value of a plurality of prediction quantization parameters isused for the following reason. When the difference quantizationparameter encoding table illustrated in FIG. 10 is used, it is importantto derive the prediction quantization parameter which can minimize thegeneration of the difference quantization parameter with a large value.In this case, the effect of averaging the errors is particularlynoticeable.

In the examples illustrated in FIGS. 14 and 15, since the quantizationcoding blocks which are spatially neighboring to each other are theprediction source of the quantization parameters, the improvement of theprediction efficiency of the quantization parameters is particularlynoticeable. That is, it is possible to predict the quantizationparameters from the quantization coding blocks which are neighboring toeach other both in order of encoding and spatially and quantizationparameter prediction suitable for both code amount control and adaptivequantization is performed.

As such, when the prediction quantization parameter is derived using thequantization parameters of a plurality of previous quantization codingblocks, it is possible to predict the quantization parameters from thespatially neighboring quantization coding blocks which have highprediction efficiency in terms of adaptive quantization, while using thequantization parameters of quantization coding blocks which are close inorder of encoding and have high prediction efficiency in terms of codeamount control. Therefore, the amount of code of the differencequantization parameter is suppressed and encoding efficiency isimproved.

FIG. 16 is a flowchart illustrating a prediction quantization parameterderivation process. First, the quantization parameter prevQP of theprevious quantization coding block in order of encoding and decoding isderived (S1000). Then, prevQP1 in which the value of the quantizationparameter of the previous quantization coding block is stored issubstituted into prevQP2 in which the value of the quantizationparameter of a quantization coding block before the previousquantization coding block is stored (S1001). Then, the quantizationparameter prevQP of the previous quantization coding block acquired inS100 is substituted into prevQP1 in which the value of the quantizationparameter of the previous quantization coding block is stored (S1002).Finally, the average value of prevQP1 and prevQP2 is calculated and isused as the prediction quantization parameter (S1003).

At the head of a picture or a slice, prevQP1 and prevQP2 are initializedby a slice QP which is described in, for example, a slice header.

FIG. 17 is a diagram illustrating an example of a predictionquantization parameter calculation process. In the actual quantizationparameter prediction process, when the quantization coding blocks areswitched, the value of prevQP1 is copied to a buffer of prevQP2 and thequantization parameter of the previous quantization coding block isloaded to the buffer which stores prevQP1. The average value calculationprocess is constantly performed on a prevQP1 buffer and a prevQP2buffer. In this way, the storage of the quantization parameters isminimized and it is possible to predict the quantization parameter witha small amount of memory. In addition, it is possible to predict thequantization parameters from the spatially neighboring quantizationcoding blocks, using the previous quantization parameter group in orderof encoding and in order of decoding, without calculating the addressesof the spatially neighboring quantization coding blocks and withoutdetermining a condition, such as whether the spatially neighboringquantization coding blocks are disposed in the tree block. Therefore, itis possible to perform quantization parameter prediction that has asmall amount of processing and is suitable for both code amount controland adaptive quantization.

In addition, an average value may be used as the quantization parameter,using a quantization parameter prevQP3 of a quantization coding blockthat is three quantization coding blocks before a target quantizationcoding block or a quantization parameter prevQP4 of a quantizationcoding block that is four quantization coding blocks before the targetquantization coding block. When the number of quantization parameters,which are a prediction source, increases, it is possible to predict thequantization parameters suitable for adaptive quantization.

Embodiment 2

Embodiment 2 differs from Embodiment 1 in that the average value of thequantization parameter of the previous encoded quantization coding blockand the quantization parameter of the encoded quantization coding blockbefore the previous encoded quantization coding block is not used, but aweighting average value is used. For prevQP1 and prevQP2, prevQP1 hashigher reliability in terms of both code amount control and adaptivequantization. Therefore, prevQP1 has a larger weighting coefficient.predQP=3.times.prevQP1+prevQP2+24  [Expression 8] ##EQU00006##

Here, the ratio of the weighting coefficients is 3:1. However, the ratioof the weighting coefficients may be other values. Therefore, thereliability of a prediction quantization parameter is improved, theamount of code of a difference quantization parameter is suppressed, andencoding efficiency is improved.

According to a moving picture encoding device of this embodiment, anoptimum prediction quantization parameter is predicted using thequantization parameters of the encoded blocks and is derived and aquantization parameter which is encoded for each block to be encoded isencoded using the difference between the quantization parameter and theprediction quantization parameter. Therefore, it is possible to reducethe amount of code of the quantization parameter and to improve encodingefficiency.

In the above description, the quantization parameter is predicted usingthe quantization coding block and the coding block as the same unit.However, the quantization parameter may be predicted, using thequantization coding block, which is the encoding and transmission unitof the quantization parameter, and the coding block as different units.

For example, the unit of the quantization coding block may be fixed anda quantization coding block size n may be encoded in a bitstream andthen transmitted. The size is represented by the product of the lengthof the side of a tree block and ½.sup.n (n is an integer greater thanand equal to 0). That is, a value obtained by shifting the length of theside of the tree block to the right by n bits is the length of the sideof the quantization coding block. Since this value is determined so asto be the same as that in the tree block structure, it has high affinitywith the tree block. In addition, since the tree block is divided intoblocks with the same size, it is possible to simply manage or read thequantization parameters stored in the coding information storagememories 113 and 204.

FIG. 18 illustrates an example in which the tree block is divided in atree block structure. The tree block has a size of 64.times.64 blocksand is hierarchically divided into four parts. 32.times.32 coding blocks(dotted rectangles in FIG. 18) are obtained by first division,16.times.16 coding blocks (hatched rectangles in FIG. 18) are obtainedby second division, and 8.times.8 coding block (white rectangles in FIG.18) are obtained by third division. Here, when the quantization codingblocks are 16.times.16 rectangular blocks, the quantization coding blockis represented by a thick dotted line in FIG. 18 and quantizationparameter prediction is performed for each quantization coding block.

When the size of the coding block to be encoded is greater than that ofthe quantization coding block size (32.times.32 blocks), for example,the inside of the coding block which is represented by a dottedrectangle in FIG. 18 is divided into four quantization coding blocks. Inthis case, the coding block is divided into four quantization codingblocks, but one quantization parameter is required for the coding block.Therefore, when the size of the coding block is greater than that of thequantization coding block, the difference quantization parameter isencoded and transmitted after the quantization parameter of the codingblock is predicted and the same quantization parameter is stored in thememory areas of the coding information storage memories 113 and 204corresponding to each of the four divided quantization coding blocks.The quantization parameters overlap each other in the memory and thequantization parameters of the neighboring encoded blocks are easilyaccessed in the prediction of the quantization parameter.

When the size of the coding block to be encoded is equal to that of thequantization coding block (16.times.16 blocks), the same predictionmethod as that for predicting the quantization parameter for each codingblock is performed.

When the size of the coding block to be encoded is less than that of thequantization coding block (8.times.8 blocks), for example, four codingblocks which are represented by white rectangles in FIG. 18 areaccommodated in the quantization coding block. Therefore, all of thecoding blocks in the quantization coding block do not have thequantization parameter, but the quantization coding block has onequantization parameter. Each coding block is encoded by the quantizationparameter.

The size of the quantization coding block may be directly described inthe header information of the bitstream, or the amount of shift of bitsindicating whether the size of the tree block is multiplied by ½.sup.n(n is an integer greater than and equal to 0) may be described in theheader information. In addition, particularly, the size of thequantization group is not described in the bitstream, but may beimplicitly determined during encoding and decoding.

The bitstream of the moving picture which is output from the movingpicture encoding device according to the above-described embodiment hasa specific data format such that it can be decoded in correspondencewith the encoding method used in the embodiment and the moving picturedecoding device corresponding to the moving picture encoding device candecode the bitstream with the specific data format.

When a wired or wireless network is used in order to exchange thebitstream between the moving picture encoding device and the movingpicture decoding device, the bitstream may be converted into a dataformat suitable for the transmission format of a communication path andthen transmitted. In this case, the following devices are provided: amoving picture transmission device that converts the bitstream outputfrom the moving picture encoding device into encoding data with a dataformat suitable for the transmission format of the communication pathand transmits the encoding data to a network; and a moving picturereception device that receives the encoding data from the network,restores the encoding data into the bitstream, and supplies thebitstream to the moving picture decoding device.

The moving picture transmission device includes a memory that buffersthe bitstream output from the moving picture encoding device, a packetprocessor that packetizes the bitstream, and a transmitter thattransmits the packetized encoding data through the network. The movingpicture reception device includes a receiver that receives thepacketized encoding data through the network, a memory that buffers thereceived encoding data, and a packet processor that performs packetprocessing on the encoding data to generate the bitstream and suppliesthe bitstream to the moving picture decoding device.

The above-mentioned encoding and decoding process can be implemented astransmission, storage, and reception devices using hardware or it can beimplemented by firmware that is stored in, for example, read only memory(ROM) or flash memory, or software if a computer. A firmware program ora software program may be stored in, for example, a computer-readablerecording medium and then provided, it may be provided from a serverthrough the wired or wireless network, or it may be provided asterrestrial or satellite digital broadcasting data.

The invention has been described above with reference to theembodiments. The embodiments are illustrative examples and it will beunderstood by those skilled in the art that various modifications incombinations of the components or the processes of these embodiments canbe made and the modifications are also included in the scope and spiritof the invention.

[Item 1]

A picture encoding device that encodes a picture and encodes adifference quantization parameter in a unit of a quantization codingblock which is divided from the picture and is a management unit of aquantization parameter, comprising:

a quantization parameter derivation unit that derives a quantizationparameter of the quantization coding block to be encoded;

a prediction quantization parameter derivation unit that derives aprediction quantization parameter using the quantization parameters of aplurality of quantization coding blocks which precede the quantizationcoding block to be encoded in order of encoding;

a difference quantization parameter derivation unit that derives adifference quantization parameter of the quantization coding block to beencoded, using a difference between the quantization parameter of thequantization coding block to be encoded and the prediction quantizationparameter; and

an encoder that encodes the difference quantization parameter. [Item 2]

The picture encoding device according to item 1,

wherein the prediction quantization parameter derivation unit derives,as the prediction quantization parameter, an average value of thequantization parameters of the plurality of quantization coding blockswhich precede the quantization coding block to be encoded in order ofencoding.

[Item 3]

The picture encoding device according to item 1 or 2,

wherein the unit of the quantization coding block is a maximum codingblock divided from the picture or a plurality of quantization codingblocks divided from the maximum coding block.

[Item 4]

The picture encoding device according to any one of items 1 to 3,

wherein the prediction quantization parameter derivation unit derivesthe prediction quantization parameter using the quantization parametersof two quantization coding blocks before the quantization coding blockto be encoded in order of encoding.

[Item 5]

A picture encoding method that encodes a picture and encodes adifference quantization parameter in a unit of a quantization codingblock which is divided from the picture and is a management unit of aquantization parameter, comprising:

a quantization parameter derivation step of deriving a quantizationparameter of the quantization coding block to be encoded;

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization coding blocks which precede the quantizationcoding block to be encoded in order of encoding;

a difference quantization parameter derivation step of deriving adifference quantization parameter of the quantization coding block to beencoded, using a difference between the quantization parameter of thequantization coding block to be encoded and the prediction quantizationparameter; and

an encoding step of encoding the difference quantization parameter.[Item 6]

A picture encoding program that encodes a picture, encodes a differencequantization parameter in a unit of a quantization coding block which isdivided from the picture and is a management unit of a quantizationparameter, and causes a computer to perform:

a quantization parameter derivation step of deriving a quantizationparameter of the quantization coding block to be encoded;

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization coding blocks which precede the quantizationcoding block to be encoded in order of encoding;

a difference quantization parameter derivation step of deriving adifference quantization parameter of the quantization coding block to beencoded, using a difference between the quantization parameter of thequantization coding block to be encoded and the prediction quantizationparameter; and

an encoding step of encoding the difference quantization parameter.

[Item 7]

A transmission device comprising:

a packet processor that packetizes a bitstream encoded by a pictureencoding method of encoding a difference quantization parameter in aunit of a quantization coding block, which is divided from a picture andis a management unit of a quantization parameter, together with thepicture to obtain a bitstream; and

a transmitter that transmits the packetized bitstream,

wherein the picture encoding method includes:

a quantization parameter derivation step of deriving a quantizationparameter of the quantization coding block to be encoded;

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization coding blocks which precede the quantizationcoding block to be encoded in order of encoding;

a difference quantization parameter derivation step of deriving adifference quantization parameter of the quantization coding block to beencoded, using a difference between the quantization parameter of thequantization coding block to be encoded and the prediction quantizationparameter; and

an encoding step of encoding the difference quantization parameter.

[Item 8]

A transmission method comprising:

a packet processing step of packetizing a bitstream encoded by a pictureencoding method of encoding a difference quantization parameter in aunit of a quantization coding block, which is divided from a picture andis a management unit of a quantization parameter, together with thepicture to obtain a bitstream; and

a transmission step of transmitting the packetized bitstream,

wherein the picture encoding method includes

a quantization parameter derivation step of deriving a quantizationparameter of the quantization coding block to be encoded,

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization coding blocks which precede the quantizationcoding block to be encoded in order of encoding,

a difference quantization parameter derivation step of deriving adifference quantization parameter of the quantization coding block to beencoded, using a difference between the quantization parameter of thequantization coding block to be encoded and the prediction quantizationparameter; and

an encoding step of encoding the difference quantization parameter.

[Item 9]

A transmission program that causes a computer to perform:

a packet processing step of packetizing a bitstream encoded by a pictureencoding method of encoding a difference quantization parameter in aunit of a quantization coding block, which is divided from a picture andis a management unit of a quantization parameter, together with thepicture to obtain a bitstream; and

a transmission step of transmitting the packetized bitstream,

wherein the picture encoding method includes

a quantization parameter derivation step of deriving a quantizationparameter of the quantization coding block to be encoded,

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization coding blocks which precede the quantizationcoding block to be encoded in order of encoding,

a difference quantization parameter derivation step of deriving adifference quantization parameter of the quantization coding block to beencoded, using a difference between the quantization parameter of thequantization coding block to be encoded and the prediction quantizationparameter, and

an encoding step of encoding the difference quantization parameter.

[Item 10]

A picture decoding device that decodes a picture and decodes a bitstreamin which a difference quantization parameter is encoded in a unit of aquantization decoding block which is divided from the picture and is amanagement unit of a quantization parameter, comprising:

a decoder that decodes the bitstream in the unit of the quantizationdecoding block and extracts a difference quantization parameter of thequantization decoding block to be decoded;

a prediction quantization parameter derivation unit that derives aprediction quantization parameter using the quantization parameters of aplurality of quantization decoding blocks which precede the quantizationdecoding block to be decoded in order of decoding; and

a quantization parameter derivation unit that adds the differencequantization parameter of the quantization decoding block to be decodedand the prediction quantization parameter to derive the quantizationparameter of the quantization decoding block to be decoded.

[Item 11]

The picture decoding device according to item 10,

wherein the prediction quantization parameter derivation unit derives,as the prediction quantization parameter, an average value of thequantization parameters of the plurality of quantization coding blockswhich precede the quantization decoding block to be decoded in order ofdecoding.

[Item 12]

The picture decoding device according to item 10 or 11,

wherein the unit of the quantization decoding block is a maximumdecoding block divided from the picture or a plurality of quantizationcoding blocks divided from the maximum decoding block.

[Item 13]

The picture encoding device according to any one of items 10 to 12,

wherein the prediction quantization parameter derivation unit derivesthe prediction quantization parameter using the quantization parametersof two quantization decoding blocks before the quantization decodingblock to be decoded in order of decoding.

[Item 14]

A picture decoding method that decodes a picture and decodes a bitstreamin which a difference quantization parameter is encoded in a unit of aquantization decoding block which is divided from the picture and is amanagement unit of a quantization parameter, comprising:

a decoding step of decoding the bitstream in the unit of thequantization decoding block and extracting a difference quantizationparameter of the quantization decoding block to be decoded;

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization decoding blocks which precede the quantizationdecoding block to be decoded in order of decoding; and

a quantization parameter derivation step of adding the differencequantization parameter of the quantization decoding block to be decodedand the prediction quantization parameter to derive the quantizationparameter of the quantization decoding block to be decoded.

[Item 15]

A picture decoding program that decodes a picture, decodes a bitstreamin which a difference quantization parameter is encoded in a unit of aquantization decoding block which is divided from the picture and is amanagement unit of a quantization parameter, and causes a computer toperform:

a decoding step of decoding the bitstream in the unit of thequantization decoding block and extracting a difference quantizationparameter of the quantization decoding block to be decoded;

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization decoding blocks which precede the quantizationdecoding block to be decoded in order of decoding; and

a quantization parameter derivation step of adding the differencequantization parameter of the quantization decoding block to be decodedand the prediction quantization parameter to derive the quantizationparameter of the quantization decoding block to be decoded.

[Item 16]

A reception device that receives a bitstream and decodes the bitstream,comprising:

a receiver that receives a bitstream obtained by packetizing a bitstreamin which a difference quantization parameter is encoded in a unit of aquantization decoding block, which is divided from a picture and is amanagement unit of a quantization parameter, together with the picture;

a restoration unit that performs packet processing on the receivedpacketized bitstream to restore the packetized bitstream to an originalbitstream;

a decoder that decodes the restored bitstream in the unit of thequantization decoding block and extracts a difference quantizationparameter of a quantization decoding block to be decoded;

a prediction quantization parameter derivation unit that derives aprediction quantization parameter using the quantization parameters of aplurality of quantization decoding blocks which precede the quantizationdecoding block to be decoded in order of decoding; and

a quantization parameter derivation unit that adds the differencequantization parameter of the quantization decoding block to be decodedand the prediction quantization parameter to derive the quantizationparameter of the quantization decoding block to be decoded.

[Item 17]

A reception method that receives a bitstream and decodes the bitstream,comprising:

a reception step of receiving a bitstream obtained by packetizing abitstream in which a difference quantization parameter is encoded in aunit of a quantization decoding block, which is divided from a pictureand is a management unit of a quantization parameter, together with thepicture;

a restoration step of performing packet processing on the receivedpacketized bitstream to restore the packetized bitstream to an originalbitstream;

a decoding step of decoding the restored bitstream in the unit of thequantization decoding block to extract a difference quantizationparameter of a quantization decoding block to be decoded;

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization decoding blocks which precede the quantizationdecoding block to be decoded in order of decoding; and

a quantization parameter derivation step of adding the differencequantization parameter of the quantization decoding block to be decodedand the prediction quantization parameter to derive the quantizationparameter of the quantization decoding block to be decoded.

[Item 18]

A reception program that receives a bitstream, decodes the bitstream,and causes a computer to perform:

a reception step of receiving a bitstream obtained by packetizing abitstream in which a difference quantization parameter is encoded in aunit of a quantization decoding block, which is divided from a pictureand is a management unit of a quantization parameter, together with thepicture;

a restoration step of performing packet processing on the receivedpacketized bitstream to restore the packetized bitstream to an originalbitstream;

a decoding step of decoding the restored bitstream in the unit of thequantization decoding block to extract a difference quantizationparameter of a quantization decoding block to be decoded;

a prediction quantization parameter derivation step of deriving aprediction quantization parameter using the quantization parameters of aplurality of quantization decoding blocks which precede the quantizationdecoding block to be decoded in order of decoding; and

a quantization parameter derivation step of adding the differencequantization parameter of the quantization decoding block to be decodedand the prediction quantization parameter to derive the quantizationparameter of the quantization decoding block to be decoded.

What is claimed is:
 1. A picture decoding device that decodes a pictureand decodes a bitstream in which a difference quantization parameter isencoded in a unit of a quantization decoding block which is divided fromthe picture and is a management unit of a quantization parameter,comprising: a decoder that decodes the bitstream in the unit of thequantization decoding block and extracts a difference quantizationparameter of a first quantization decoding block to be decoded; aprediction quantization parameter derivation unit that derives aprediction quantization parameter by averaging the quantizationparameters of two quantization decoding blocks which precede the firstquantization decoding block to be decoded in order of decoding; and aquantization parameter derivation unit that adds the differencequantization parameter of the first quantization decoding block to bedecoded and the prediction quantization parameter to derive thequantization parameter of the first quantization decoding block to bedecoded, wherein the prediction quantization parameter derivation unitderives the prediction quantization parameter using two quantizationparameters: one quantization parameter of a previous quantizationdecoding block which immediately precedes the first quantizationdecoding block to be decoded in order of decoding and anotherquantization parameter of a quantization decoding block which precedesthe previous quantization decoding block in order of decoding and is notspatially neighboring the first quantization decoding block to bedecoded.
 2. A picture decoding method that decodes a picture and decodesa bitstream in which a difference quantization parameter is encoded in aunit of a quantization decoding block which is divided from the pictureand is a management unit of a quantization parameter, comprising: adecoding step of decoding the bitstream in the unit of the quantizationdecoding block and extracting a difference quantization parameter of afirst quantization decoding block to be decoded; a predictionquantization parameter derivation step of deriving a predictionquantization parameter by averaging the quantization parameters of twoquantization decoding blocks which precede the first quantizationdecoding block to be decoded in order of decoding; and a quantizationparameter derivation step of adding the difference quantizationparameter of the first quantization decoding block to be decoded and theprediction quantization parameter to derive the quantization parameterof the first quantization decoding block to be decoded, wherein theprediction quantization parameter derivation step derives the predictionquantization parameter using two quantization parameters: onequantization parameter of a previous quantization decoding block whichimmediately precedes the first quantization decoding block to be decodedin order of decoding and another quantization parameter of aquantization decoding block which precedes the previous quantizationdecoding block in order of decoding and is not spatially neighboring thefirst quantization decoding block to be decoded.